Optical fiber unit, laser system comprising such an optical fiber unit, and method for evaluating an input coupling quality of the input coupling of useful light into such an optical fiber unit

The invention claimed is: 1. An optical fiber unit comprising: an optical fiber comprising a light guiding region configured for guiding useful light through the optical fiber and a cladding region extending around the light guiding region in a circumferential direction, an input coupling end having a first fiber end surface for coupling the useful light into the light guiding region, and an output coupling end having a second fiber end surface for coupling the useful light out of the light guiding region, a first end piece arranged at one of the input coupling end and the output coupling end, the first end piece being configured to couple the useful light into the light guiding region or couple the useful light out of the light guiding region, wherein the first end piece comprises a reflection element configured to divert a portion of the useful light propagating along a direction of propagation through the light guiding region away from the direction of propagation, and a measuring device configured to capture the portion of the useful light diverted by the reflection element, and to evaluate an input coupling quality of input coupling of the useful light into the light guiding region of the optical fiber based on the captured portion of the useful light. 2. The optical fiber unit as claimed in claim 1 , further comprising a second end piece arranged at another one of the output coupling end and the input coupling end, the second end piece being configured to couple the useful light into the light guiding region or couple the useful light out of the light guiding region. 3. The optical fiber unit as claimed in claim 1 , wherein the first end piece is arranged at the output coupling end, wherein the reflection element is configured to reflect the useful light coupled out of the light guiding region so as to be coupled back into the light guiding region counter to the direction of propagation. 4. The optical fiber unit as claimed in claim 1 , wherein the first end piece is arranged at the input coupling end, wherein the reflection element is configured to divert the portion of the useful light away from a beam axis of the light at a first angle. 5. The optical fiber unit as claimed in claim 2 , wherein the first end piece is arranged at the output coupling end, wherein the reflection element is configured to reflect the useful light so as to be coupled back into the light guiding region counter to the direction of propagation, wherein the second end piece is arranged at the input coupling end and comprises a further reflection element, wherein the further reflection element is configured to divert a second portion of the useful light away from a beam axis of the light at a first angle. 6. The optical fiber unit as claimed in claim 2 , wherein the first end piece is arranged at the output coupling end, wherein the reflection element is configured to reflect the useful light so as to be coupled back into the light guiding region counter to the direction of propagation, wherein the second end piece is arranged at the input coupling end and comprises a measurement reflection element, the measurement reflection element being configured to divert a second portion of the useful light, the second portion of the useful light to be guided back through the light guiding region, away from a beam axis of the light at a second angle, in a direction of a measuring device. 7. The optical fiber unit as claimed in claim 1 , wherein the first end piece further comprises an optical beam shaping element for beam shaping of the useful light. 8. The optical fiber unit as claimed in claim 1 , wherein the reflection element is nonreleasably secured to the first end piece via a securing tube, by welding or adhesive bonding. 9. The optical fiber unit as claimed in claim 1 , wherein the reflection element is configured as an element selected from a group consisting of: a plane-parallel plate, a window, and a beam shaping element, a diffractive optical element, a waveplate, an axicon, and a wedge. 10. The optical fiber unit as claimed in claim 1 , wherein the reflection element is configured as a lens. 11. The optical fiber unit as claimed in claim 1 , wherein the optical fiber is configured as a hollow core photonic crystal fiber, as a photonic band gap fiber, as an antiresonant fiber, or as an inhibited coupling fiber. 12. The optical fiber unit as claimed in claim 1 , wherein the optical fiber is configured as a tubular fiber, or as a Kagomé fiber. 13. The optical fiber unit as claimed in claim 1 , wherein the first end piece is configured as an end cap, or an end cap with a supplementary piece, or a plug. 14. The optical fiber unit as claimed in claim 1 , wherein the reflection element is provided with a first antireflection coating having a first reflectance at a front end face with respect to the direction of propagation of the light, and a second antireflection coating having a second reflectance at a rear end face with respect to the direction of propagation of the light, and wherein the first reflectance is greater than the second reflectance. 15. A laser system comprising a laser radiation source for emitting light, an optical fiber unit as claimed in claim 1 , and a coupling device for coupling the light into the optical fiber unit. 16. The laser system as claimed in claim 15 , wherein the measuring device comprises a light measuring device, wherein the light measuring device is configured to capture a light power and/or a mode profile of the captured portion of the useful light, and/or to determine an angle deviation from a predetermined angle between a beam path of the captured portion of the useful light and the direction of propagation. 17. The laser system as claimed in claim 15 , wherein the measuring device comprises a controller, wherein the coupling device comprises a controllable aligning device for aligning the input coupling of the light into the optical fiber unit, wherein the controller is operatively connected to the aligning device and is configured to control the aligning device based on the captured portion of the useful light. 18. The laser system as claimed in claim 15 , wherein the measuring device is further configured to capture a further portion of the light, the further portion of the light being guided away from a beam path of the light before the input coupling into the optical fiber unit, wherein the measuring device is further configured to evaluate a processing process carried out using the useful light with the laser system based on the captured portion of the useful light and the captured further portion of the light.